Author :
Choi, K. ; Jagannathan, H. ; Choi, C. ; Edge, L. ; Ando, T. ; Frank, M. ; Jamison, P. ; Wang, M. ; Cartier, E. ; Zafar, S. ; Bruley, J. ; Kerber, A. ; Linder, B. ; Callegari, A. ; Yang, Q. ; Brown, S. ; Stathis, J. ; Iacoponi, J. ; Paruchuri, V. ; Narayan
Author_Institution :
Adv. Micro Devices Inc., Yorktown Heights, NY, USA
Abstract :
We report for the first time that extreme EOT scaling and low n/p VTHs can be achieved simultaneously. Underlying mechanisms that enable EOT scaling and EWF tuning are explained and the fundamental device parameters including reliability of the extremely scaled devices are discussed. Record low gate leakage, appropriately low VTHs and competitive carrier mobilities in this work demonstrate the gate stack technology that is consistent with the sub-22 nm node requirements.
Keywords :
MOSFET; carrier mobility; permittivity; semiconductor device reliability; EOT; carrier mobility; effective work function; equivalent oxide thickness; extreme EOT scaling; high-k/metal gate stack; interfacial layer scavenging; low gate leakage; reliability; threshold voltage; Alloying; Capacitance-voltage characteristics; Channel bank filters; Electrodes; Electron mobility; Hafnium oxide; High K dielectric materials; High-K gate dielectrics; MOSFETs; Tin;
